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Simpson rule Composite Simpson rule. Simpson rule for numerical integration. y=sin(x) for x within [1.2 2]. a=1.2;b=2; x= linspace (a,b);plot(x,sin(x));hold on. Quadratic polynomial. Approximate sin using a quadratic polynomial . c=0.5*(a+b); x=[a b c]; y=sin(x); p=polyfit(x,y,2);
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Simpson rule Composite Simpson rule 數值方法2008, Applied Mathematics NDHU
Simpson rule for numerical integration 數值方法2008, Applied Mathematics NDHU
y=sin(x) for x within [1.2 2] a=1.2;b=2; x=linspace(a,b);plot(x,sin(x));hold on 數值方法2008, Applied Mathematics NDHU
Quadratic polynomial • Approximate sin using a quadratic polynomial c=0.5*(a+b); x=[a b c]; y=sin(x); p=polyfit(x,y,2); z=linspace(a,b); plot(z,polyval(p,z),'r') 數值方法2008, Applied Mathematics NDHU
Approximate sin(x) within [1 3] by a quadratic polynomial a=1;b=3; x=linspace(a,b);plot(x,sin(x)) hold on; c=0.5*(a+b); x=[a b c]; y=sin(x); p=polyfit(x,y,2); z=linspace(a,b); plot(z,polyval(p,z) ,'r') 數值方法2008, Applied Mathematics NDHU
Approximate sin(x) within [1 3] by a line a=1;b=3; x=linspace(a,b);plot(x,sin(x)) hold on; c=0.5*(a+b); x=[a b ]; y=sin(x); p=polyfit(x,y,1); z=linspace(a,b); plot(z,polyval(p,z) ,'r') 數值方法2008, Applied Mathematics NDHU
Strategy I : Apply Trapezoid rule to calculate area under a line Strategy II : Apply Simpson rule to calculate area under a second order polynomial Strategy II is more accurate and general than strategy I, since a line is a special case of quadratic polynomial 數值方法2008, Applied Mathematics NDHU
Simpson rule • Original task: integration of f(x) within [a,b] • c=(a+b)/2 • Numerical task • Approximate f(x) within [a,b] by a quadratic polynomial, p(x) • Integration of p(x) within [a,b] 數值方法2008, Applied Mathematics NDHU
Blue: f(x)=sin(x) within [1,3] Red: a quadratic polynomial that pass (1,sin(1)), (2,sin(2)),(3,sin(3)) 數值方法2008, Applied Mathematics NDHU
The area under a quadratic polynomial is a sum of area I, II and III 數值方法2008, Applied Mathematics NDHU
The area under a quadratic polynomial is a sum of area I, II and III • Partition [a,b] to three equal-size intervals, • and use the high of the middle point c to produce three Trapezoids • Use the composite Trapezoid rule to determine area I, II and III • h/2*(f(a)+f(c) +f(c)+f(c)+ f(c)+f(b)) • substitute h=(b-a)/3 and c=(a+b)/2 • area I + II + III = (b-a)/6 *(f(a)+4*f((a+b)/2) +f(b)) 數值方法2008, Applied Mathematics NDHU
Shift Lagrange polynomial Rescale Lagrange polynomial 數值方法2008, Applied Mathematics NDHU
Shortcut to Simpson 1/3 rule • Partition [a,b] to three equal intervals • Draw three trapezoids, Q(I), Q(II) and Q(III) • Calculate the sum of areas of the three trapezoids 數值方法2008, Applied Mathematics NDHU
Proof 數值方法2008, Applied Mathematics NDHU
Composite Simpson rule • Partition [a,b] into n interval • Integrate each interval by Simpson rule • h=(b-a)/2n 數值方法2008, Applied Mathematics NDHU
Apply Simpson sule to each interval 數值方法2008, Applied Mathematics NDHU
Composite Simpson rule 數值方法2008, Applied Mathematics NDHU
Set n Set fx h=(b-a)/(2*n) ans=0; exit for i=0:n-1 aa=a+2*i*h; cc=aa+h;bb=cc+h; ans=ans+h/3*(fx(aa)+4*fx(cc)+fx(bb)) 數值方法2008, Applied Mathematics NDHU
Composite Simpson rule h=(b-a)/2n 數值方法2008, Applied Mathematics NDHU
Composite Simpson rule h=(b-a)/2n Simpson's Rule for Numerical Integration 數值方法2008, Applied Mathematics NDHU